MAAP #218: Killing of Environmental Defenders in the Peruvian Amazon

 

Peruvian environmental defender Edwin Chota was murdered by illegal loggers in 2014 for attempting to protect his Indigenous community from Exploitation. See Illegal Logging section. Photo: NYT/Tomas Munita.

 

 

 

 

 

 

 

 

 

 

 

 

 

Amazon Conservation’s MAAP program specializes in reporting on the most urgent deforestation threats facing the Amazon and producing big-picture analyses of key Amazon-wide issues.

This report uniquely presents a view into the complicated but critical issue of murders of environmental defenders, examining the relationship between the location of these killings and deforestation in the Peruvian Amazon to provide a better understanding of the context of their deaths.

Between 2010 and 2022, an estimated 29 Peruvian environmentalists and Indigenous leaders were killed while defending various parts of Peru’s Amazon from invaders seeking to exploit its resources (RAISG 2022).

Importantly, the frequency of these murders has increased in recent years, with nearly half (14 out of 29) occurring since 2020.

Our findings indicate that these murders are connected to five major issues in the Peruvian Amazon:
Illegal gold mining, Illegal logging, Illicit crops (coca), Land trafficking, and Protesting.

This report focuses on the first three (Illegal gold mining, Illegal logging, and Illicit crops).

Base Map

Base Map. Location of the 29 environmental defenders murdered in Peru and the suspected causes related to major environmental threats in the region 2010-2022. Sources: IBC, MINJUS, SERNANP, Conservación Amazónica-ACCA.

The Base Map shows the location of the 29 documented environmental defenders killed in Peru between 2010-2022.

It also indicates the environmental threat related to each death as the suspected or confirmed motive for the crime: Illegal Gold Mining, Illegal Logging, Illicit Crops (coca), Land Trafficking, and Protest.

Note that many of the murders occurred in geographic clusters that coincide with the major environmental conflict of that specific area.

For example, gold mining is a major cause of conflict in the southern Peruvian Amazon, while illegal logging and illicit crops are more common threats in the central Peruvian Amazon.

Murders related to Illegal Gold Mining

Illegal gold mining has long been, and continues to be, a major issue in the southern Peruvian Amazon (Madre de Dios region), particularly in Indigenous territories and protected area buffer zones (MAAP#208).

For example, Figure 1 illustrates the extensive gold mining deforestation (indicated in orange) in the Tambopata National Reserve buffer zone and surrounding Indigenous territories.

Figure 1. Three cases of environmental defender deaths related to illegal mining. Sources: IBC, MINJUS, SERNANP, Conservación Amazónica-ACCA.

Since 2015, three environmental defenders have been killed within or near the Tambopata National Reserve buffer zone (see yellow dots in Figure 1). All three cases involved forestry concessionaires trying to defend their concession from illegal mining invasion.

In 2015, Alfredo Vracko Neuenschwander was killed near the critical mining area known as “La Pampa” located in the core of the buffer zone. Note that during the two years prior to his death, more than 1,700 hectares were deforested in La Pampa due to illegal gold mining (MAAP #1). Vracko, who was president of the Madre de Dios Federation of Forestry and Reforestation Concessionaires at the time, is believed to have been killed by illegal miners who were scheduled to be evicted from his forestry concession on the same day. However, his murder remains officially unsolved.

In 2020, Roberto Carlos Pacheco Villanueva was killed just outside the Tambopata buffer zone. Villanueva owned a forestry concession that had been illegally deforested and burned by invaders linked to illegal mining. Having filed legal complaints about the illegal use of his land, Villanueva faced numerous threats against his life in the years leading up to his murder. While still unsolved, it is believed that his murder was committed by the same miners who invaded his concession.

More recently, in 2022, Juan Julio Fernández Hanco was murdered just off the Interoceanic Highway near the edge of the Tambopata buffer zone. During this period (2021-2023), nearly 24,000 hectares were deforested due to gold mining in this area (MAAP #195). The investigation is ongoing, with the suspects being illegal miners who invaded Juan Julio’s reforestation concessions.

Murders related to Illegal Logging

Illegal logging has been a significant problem across the Peruvian Amazon for years. A recent report revealed that over 20% of timber harvested in Peru in 2021 came from illegal origins (OSINFOR, 2024). Loreto, Madre de Dios, Amazonas, and Ucayali were identified as the regions with the highest levels of unauthorized timber extraction.

Figure 2. Four environmental defender deaths related to illegal logging. Sources: IBC, MINJUS, DEVIDA, SERNANP, ACCA.

In 2014, illegal loggers murdered four men from the community of Alto Tamaya-Saweto, in one of the most well-known murder cases of Peruvian environmental defenders. These defenders (Edwin Chota Valera, Francisco Pinedo Ramírez, Jorge Ríos Pérez, and Leoncio Quintisima Meléndez) were killed along the Peru-Brazil border (see orange dots in Figure 2), following a decade of complaints from Chota about the presence of criminal logging groups in their community. Ten years later, in April 2024, a group of loggers were found guilty of the murders and sentenced to nearly 30 years in prison. This case has since been appealed with the expectation of going to Peru’s supreme court.

Murders related to Illicit Crops (Coca)

Official data indicates that the surface area of coca production in Peru continues to increase, particularly in the central Peruvian Amazon along the Andes Mountains (in the regions of Ucayali and Huánuco). Since 2010, ten environmental defenders have been killed in this area related to their fight against coca-related activities (see red dots in Figure 3).

Figure 3. Ten cases of environmental defender deaths related to illegal coca production. Sources: IBC, MINJUS, DEVIDA, SERNANP, Conservación Amazónica-ACCA.

Three environmental defenders (Santiago Vega Chota, Yenes Ríos Bonsano, and Herasmo García Grau) were killed in 2020 and 2021 within or near their communities of Sinchi Roca and Puerto Nuevo in the region of Ucayali, following their attempts to monitor their communities’ territories for coca production. Both communities are located within a coca production zone known as Aguaytía, which experienced a 158% increase in coca cultivation between 2018 and 2022 (DEVIDA 2022).

Between 2010 and 2020, four environmental defenders (Segundo José Reategui, Manuel Tapullima, Justo Gonzales Sangama, and Arbildo Melendez) were murdered in or near the Unipacuyacu Indigenous community. These four deaths have been linked to illegal coca production by outsiders on community lands that have not yet been officially titled by the government, which has facilitated these invasions. Unipacuyacu is located within the Pichis-Palcazu-Pachitea coca production zone spanning the Huánuco and Pasco regions, where coca cultivation increased by more than 450% between 2018 and 2022 (DEVIDA 2022).

Finally, three other environmental defenders (Jesús Berti Antaihua Quispe, Gemerson Pizango Narvaes, and Nusat Parisada Benavides de la Cruz) were killed in 2022 in their communities of Santa Teresa and Cleyton. These two indigenous communities are located within and just outside of the in an area outside of the El Sira Communal Reserve buffer zone. During the four years leading up to their deaths, coca production in El Sira and its buffer zone increased by over 500% (DEVIDA 2022). While unconfirmed, it is believed that these murders were committed by mafias tied to drug trafficking and illegal mining.

Regulatory Basis

Peru ranks among the countries with the highest number of environmental defender deaths worldwide (Global Witness 2023).

Peru’s National Plan for Human Rights 2018-2021, defines an environmental defender as someone who: As an individual or collective, carries out a legitimate activity, paid or not, consisting of demanding and promoting, within the legally permitted framework, in a peaceful and nonviolent manner, the effectiveness of violated rights. Their efforts are usually manifested publicly through demands and raised through regular process channels, conforming with the framework devoted to these fundamental rights.

To address the vulnerability of environmental defenders, the Peruvian government, specifically the Ministry of Justice and Human Rights (MINJUSDH), has developed regulations to ensure their protection. The most important of these are:

Regulation Title Importance
 

Supreme Decree N 002-2018-JUS

 

National Plan for Human Rights 2018-2021

Establishes that environmental defenders are a group of special protection and requests that the state adopts measures to protect them.
 

Supreme Decree 004-2021-JUS

 

Intersectoral Mechanism for the Protection of Human Rights Defenders

Establishes the principles, measures, and proceedings to guarantee the prevention, protection, and access to justice for human rights defenders prior to risk situations, being the highest ranking standard in the country.
 

Ministerial Resolution 255-2020-JUS

 

Registry on Risk Situations for Human Rights Defenders

 

Recognizes, analyzes, and manages information about the risks that human rights defenders face, and adopts actions to prevent threats.

 

Peru has also taken an intersectoral approach by coordinating participation among eight ministries: Ministry of Justice and Human Rights, Ministry of the Interior, Ministry of the Environment, Ministry of Culture, Ministry of Woman and Vulnerable Populations, Ministry of External Relations, Ministry of Energy and Mines, and Ministry of Agriculture and Irrigation Development. A public implementing agency, the National Commission for Development and Life Without Drugs (DEVIDA), also cooperates with this effort.

Despite these efforts, defenders continue to face criminalization, legal harassment, and threats of violence and murder. This shows the urgent need to strengthen their protection and institutional support in Peru.

In response, the Peruvian Congress has recently enacted three new laws to further protect human rights defenders. These include (i) Bill 4686/2022-CR, a law that recognizes and protects defenders of environmental rights, and (ii) Bill 2069/2021-PE, a law for the protection and assistance of communal and/or Indigenous or native leaders at risk. Moving forward, how the ongoing Alto Tamaya-Saweto case proceeds through Peru’s Supreme Court will be crucial to future efforts to protect environmental and human rights defenders.

References

Comisión Nacional Para El Desarrollo y Vida Sin Drogas (DEVIDA). 2023. Perú: Monitoreo de cultivos de coca 2022.

Global Witness 2023. Casi 2.000 personas defensoras de la tierra y el medioambiente asesinadas entre 2012 y 2022 por proteger el planeta.

Organismo de Supervisión de los Recursos Forestales y de Fauna Silvestre (OSINFOR). 2024. Estimación del índice y porcentaje de tala y comercio ilegal de madera en el Perú 2021.

Red Amazónica de Información Socioambiental Georreferenciada (RAISG). 2022. Presiones, amenazas y violencia en la Amazonía peruana.

Acknowledgments

This report was prepared with support from the Instituto de Bien Común (IBC).

Citation

Montoya M, Bonilla A, Novoa S, Tipula P, Salisbury D, Quispe M, Finer M, Folhadella A, Cohen M (2024) Killing of Environmental Defenders in the Peruvian Amazon. MAAP:218.

MAAP Interactive: Deforestation Drivers in the Andean Amazon

Since its launch in April 2015, MAAP has published over 70 reports related to deforestation (and natural forest loss) in the Andean Amazon. We have thus far focused on Peru, with several reports in Colombia and Brazil as well.

These reports are meant to be case studies of the most important and urgent deforestation events. We often use forest loss alerts (known as GLAD) to guide us, and satellite imagery (from Planet and DigitalGlobe) to identify the deforestation driver.

Here we present an interactive map highlighting the drivers identified in all published MAAP reports. These drivers include gold mining, agriculture (e.g. oil palm and cacao), cattle pasture, roads, and dams (see icon legend below map). We also include natural causes such as floods and blowdowns (fire included under agriculture since most human caused). Furthermore, we highlight deforestation events within protected areas. Note that you can filter by driver by checking boxes of interest.

We hope the result is one of the most detailed and up-todate resources on patterns and drivers of deforestation in the Andean Amazon. Over the coming year we will continue to focus on Peru and Colombia, and begin to include Ecuador and Bolivia as well.

To view the interactive map, please visit:

MAAP Interactive: Deforestation Drivers in the Andean Amazon
https://www.maapprogram.org/interactive/

For more information on patterns and drivers of deforestation in the Peruvian Amazon, see our latest Synthesis report 

MAAP #65: Deforestation Hotspots of 2017 in the Peruvian Amazon

Image 65. Data: MINAM/PNCB, UMD/GLAD, SERNANP, MAAP

In an earlier report, MAAP #40, we highlighted the power of combining early warning GLAD* alerts with analysis of high-resolution satellite images (for example, from the company Planet), as part of a comprehensive near real-time deforestation monitoring system.

In the current report, we analyze the GLAD alerts for the first half of 2017 (through July 17) to identify current deforestation hotspots in the Peruvian Amazon.** These alerts indicate an estimated total forest loss of 37,000 acres (15,000 hectares) thus far during the year.

Image 65 (see right) highlights the 2017 deforestation hotspots, defined here as areas with medium to high density of forest loss.

Below, we describe and show images of the most intense hotspots, indicated in red and orange.

These areas include:

  • Buffer zones of Tambopata National Reserve and Cordillera Azul National Park
  • Natural loss due to blowdowns from “hurricane winds,” in the Madre de Dios region
  • Northwest border with Colombia

 

 

 

 

Buffer Zone of Tambopata National Reserve 

Inset A indicates an area of high intensity deforestation due to gold mining activity in the buffer zone of Tambopata National Reserve in the southern Peruvian Amazon (Madre de Dios region). Image 65a shows the deforestation of 1,210 acres (490 hectares) in this area in 2017. The Peruvian government recently (early July) led a major raid in this area. However, the most recent satellite images (late July – early August) indicate that mining camps are still present in the area.

Image 65a. Data: Planet

Hurricane Winds

Insets B and C indicate two areas in the southern Peruvian Amazon (Madre de Dios region) that experienced the natural forest loss of 980 acres (400 hectares) caused by hurricane winds, localized thunderstorms with strong winds. Images 65b and 65c show the recent 2017 forest loss. See MAAP #54 and MAAP #55 for more details about hurricane winds.

Image 65b. Data: Planet
Image 65c. Data: Planet

Buffer Zone of Cordillera Azul National Park

Inset D shows an area of medium intensity deforestation in the buffer zone of Cordillera Azul National Park, in the central Peruvian Amazon (San Martin region). Image 65d shows an example of the deforestation (138 acres) in this area in 2017. The main cause of the deforestation appears to be agricultural activity.

Image 65d. Data: Planet

Northwest Border with Colombia

Inset E indicates a medium intensity hotspot in the extreme northern Peruvian Amazon (Loreto region), along the border with Colombia. The deforestation is approaching the limit of the Huimeki Communal Reserve. Image 65e shows the deforestation of 390 acres (158 hectares) in this area in 2017. The driver appears to be linked to agricultural activities and illicit crops (The United Nations has confirmed coca in this area).

Image 65e. Data: Planet

Notes

*GLAD alerts are a powerful new tool to monitor tropical forest loss in near real-time. This early warning system, created by the GLAD (Global Land Analysis and Discovery) laboratory at the University of Maryland and supported by Global Forest Watch, was launched in March 2016 as the first Landsat-based (30-meter resolution) forest loss alert system (previous systems were based on lower-resolution imagery). The alerts are updated weekly and can be accessed through Global Forest Watch.

**We performed a kernel density estimation, an analysis that calculates the magnitude per unit area of a particular phenomenon, in this case, forest loss.

Reference

Planet Team (2017). Planet Application Program Interface: In Space for Life on Earth. San Francisco, CA. https://api.planet.com.

Citation

Novoa S, Finer M (2017) Deforestation Hotspots in the Peruvian Amazon in 2017. MAAP: 65.

 

MAAP SYNTHESIS #2: PATTERNS AND DRIVERS OF DEFORESTATION IN THE PERUVIAN AMAZON

We present our second synthesis report, building off our first report published in September 2015. This synthesis is largely based on the 50 MAAP reports published between April 2015 and November 2016. The objective is to synthesize all the information to date regarding deforestation trends, patterns and drivers in the Peruvian Amazon.

MAAP methodology includes 4 major components: Forest loss detection, Prioritize big data, Identify deforestation drivers, and Publish user-friendly reports. See Methodology section below for more details.

Our major findings include:

  • Trends. During the 15 years between 2001 and 2015, around 4,448,000 acres (1,800,000 hectares) of Peruvian Amazon forest has been cleared, with a steadily increasing trend. 2014 had the highest annual forest loss on record (438,775 acres), followed by a slight decrease  in 2015. The preliminary estimate for 2016 indicates that forest loss remains relatively high. The vast majority (80%) of forest loss events in the Peruvian Amazon are small-scale (<5 hectares), while large-scale events (> 50 hectares) pose a latent threat due to new agro-industrial projects.
  • Hotspots. We have identified at least 8 major deforestation hotspots. The most intense hotspots are located in the central Amazon (Huánuco and Ucayali). Other important hotspots are located in Madre de Dios and San Martin. Two protected areas (Tambopata National Reserve and El Sira Communal Reserve) are threatened by these hotspots.
  • Drivers. We present an initial deforestation drivers map for the Peruvian Amazon. Analyzing high-resolution satellite imagery, we have documented six major drivers of deforestation and degradation: small/medium-scale agriculture, large-scale agriculture, cattle pasture, gold mining, illegal coca cultivation, and roads. Small-scale agriculture and cattle pasture are likely the most dominant drivers overall. Gold mining is a major driver in southern Peru. Large-scale agriculture and major new roads are latent threats. Logging roads are likely a major source of forest degradation in central Peru.

Deforestation Trends

Image 1 shows forest loss trends in the Peruvian Amazon from 2001 to 2015, including a breakdown of the size of the forest loss events. This includes the official data from the Peruvian Environment Ministry, except for 2016, which is a preliminary estimate based on GLAD forest loss alerts.

Image 1. Data: PNCB/MINAM, UMD/GLAD. *Estimate based on GLAD alerts.

During the 15 years between 2001 and 2015, around 4,448,000 acres (1,800,000 hectares) of Peruvian Amazon forest has been cleared (see green line). This represents a loss of approximately 2.5% of the existing forest as of 2001.There have been peaks in 2005, 2009, and 2014, with an overall increasing trend. In fact, 2014 had the highest annual forest loss on record (386,626 acres). Forest loss decreased in 2015 (386,732 acres), but is still the second highest recorded. The preliminary estimate for 2016 indicates that forest loss continues to be relatively high.

It is important to note that the data include natural forest loss events (such as storms, landslides, and river meanders), but overall serves as our best proxy for anthropogenic deforestation. The non-anthropogenic forest loss is estimated to be approximately 3.5% of the total.1

The vast majority (81%) of forest loss events in the Peruvian Amazon are small-scale (<5 hectares, equivalent of 12 acres), see the yellow line. Around 16% of the forest loss events are medium-scale (5-50 hectares, equivalent of 12-124 acres), see the orange line. Large-scale (>50 hectares, equivalent of 124 acres) forest loss events, often associated with industrial agriculture, pose a latent threat. Although the average is only 2%, large-scale forest loss rapidly spiked to 8% in 2013 due to activities linked with a pair of new oil palm and cacao plantations. See MAAP #32 for more details on the patterns of sizes of deforestation events.

Deforestation Patterns

Image 2 shows the major deforestation hotspots in 2012-14 (left panel) relative to 2015-16 (right panel), based on a kernel density analysis.We have identified at least 8 major deforestation hotspots, labeled as Hotspots A-H.

Image 2. Data: PNCB/MINAM, GLAD/UMD. Click to enlarge.

The most intense hotspots, A and B, are located in the central Amazon. Hotspot A, in northwest Ucayali, was dominated by two large-scale oil palm projects in 2012-14, but then shifted a bit to the west in 2015-16, where it was dominated by cattle pasture and small-scale oil palm. Hotspot B, in eastern Huánuco, is dominated by cattle pasture (MAAP #26).

Hotspots C and D are in the Madre de Dios region in the southern Amazon. Hotspot C indicates the primary illegal gold mining front in recent years (MAAP #50). Hotspot D highlights the emerging deforestation zone along the Interoceanic Highway, particularly around the town of Iberia (MAAP #28).

Hotspots E-H are agriculture related. Hotspot E indicates the rapid deforestation for a large-scale cacao plantation in 2013-14, with a sharp decrease in forest loss 2015-16 (MAAP #35). Hotspot F indicates the expanding deforestation around two large-scale oil palm plantation (MAAP #41). Hotspot G indicates the intensifying deforestation for small-scale oil palm plantations (MAAP #48).

Hotspot H indicates an area impacted by intense wildfires in 2016.

Protected Areas, in general, are effective barriers against deforestation (MAAP #11). However, several protected areas are currently threatened, most notably Tambopata National Reserve (Hotspot C; MAAP #46). and El Sira Communal Reserve (Hotspot B; MAAP #45).

Deforestation Drivers

Image 3. Data: MAAP, SERNANP. Click to enlarge.

Surprisingly, there is a striking lack of precise information about the actual drivers of deforestation in the Peruvian Amazon. According to an important paper published in 2016, much of the existing information is vague and outdated, and is based solely on a general analysis of the size of deforestation events.3  

As noted above, one of the major advances of MAAP has been using high-resolution imagery to better identify deforestation drivers.

Image 3 shows the major deforestation drivers identified thus far by our analysis. As far as we know, it represents the first spatially explicit deforestation drivers map for the Peruvian Amazon.

To date, we have documented six major direct drivers of deforestation and degradation in the Peruvian Amazon: small/medium-scale agriculture, large-scale agriculture, cattle pasture, gold mining, illegal coca cultivation, and roads.

At the moment, we do not consider the hydrocarbon (oil and gas) and hydroelectric dam sectors as major drivers in Peru, but this could change in the future if proposed projects move forward.

We describe these major drivers of deforestation and degradation in greater detail below.

Small/Medium-scale Agriculture

The literature emphasizes that small-scale agriculture is the leading cause of deforestation in the Peruvian Amazon.However, there is little actual empirical evidence demonstrating that this is true.3 The raw deforestation data is dominated by small-scale clearings that are most likely for agriculture or cattle pasture. Thus, it is likely that small-scale agriculture is a major driver, but a definitive study utilizing high-resolution imagery and/or extensive field work is still needed to verify the assumption.

In several key case studies, we have shown specific examples of small-scale agriculture being a deforestation driver. For example, using a combination of high-resolution imagery, photos from the field, and local sources, we have determined that:

  • Oil Palm, in the form of small and medium-scale plantations, is one of the main drivers within deforestation Hotspot B (Ucayali; MAAP #26), Hotspot G (northern Huánuco; MAAP #48), and Hotspot F (Loreto-San Martin;MAAP #16). This was also shown for Ucayali in a recent peer-reviewed study.4 See below for information about large-scale oil palm.
  • Cacao is causing rapid deforestation along the Las Piedras River in eastern Madre de Dios (MAAP #23, MAAP #40). See below for information about large-scale cacao.
  • Papaya is an important new driver in Hotspot D, along the Interoceanic Higway in eastern Madre de Dios (MAAP #42).
  • Corn and rice plantations may also be an important driver in Hotspot D in eastern Madre de Dios (MAAP #28).

Large-scale Agriculture

Large-scale, agro-industrial deforestation remains a latent threat in Peru, particularly in the central and northern Amazon regions. This issue was put on high alert in 2013, with two cases of large-scale deforestation for oil palm and cacao plantations, respectively.

In the oil palm case, two companies that are part of the Melka group,5 cleared nearly 29,650 acres in Hotspot A in Ucayali between 2012 and 2015 (MAAP #4, MAAP #41). In the cacao case, another company in the Melka group (United Cacao) cleared 5,880 acres in Hotspot E in Loreto between 2013 and 2015 (MAAP #9, MAAP #13, MAAP #27, MAAP #35). Dennis Melka has explicitly stated that his goal is to bring the agro-industrial production model common in Southeast Asia to the Peruvian Amazon.6

Prior to these cases, large-scale agricultural deforestation occurred between 2007 and 2011, when oil palm companies owned by Grupo Palmas7 cleared nearly 17,300 acres for plantations in Hotspot H along the Loreto-San Martin border (MAAP #16). Importantly, we documented the additional deforestation of 24,215 acres for oil palm plantations surrounding the Grupo Palmas projects (MAAP #16).

In contrast, large-scale agricultural deforestation was minimal in 2015 and 2016. However, as noted above, it remains a latent threat. Both United Cacao and Grupo Palmas have expansion plans that would clear over 49,420 acres of primary forest in Loreto.8

Cattle Pasture

Using an archive of satellite imagery, we documented that deforestation for cattle pasture is a major issue in the central Peruvian Amazon. Immediately following a deforestation event, the scene of hundreds or thousands of recently cut trees often looks the same whether the cause is agriculture or cattle pasture. However, by using an archive of imagery and studying deforestation events from previous years, one can more easily determine the drivers of the forest loss. For example, after a year or two, agriculture and cattle pasture appear very differently in the imagery and thus it is possible to distinguish these two drivers.

Using this technique, we determined that cattle pasture is a major driver in Hotspots A and B, in the central Peruvian Amazon (MAAP #26, MAAP #37).

We also used this technique to determine that much of the deforestation in the northern section of El Sira Communal Reserve is due to cattle pasture (MAAP #45).

Maintenance of cattle pasture, and small-scale agriculture, are likely important factors behind the escaped fires that degrade the Amazon during intense dry seasons (MAAP #45, MAAP #47).

Gold Mining

Gold mining is one of the major drivers of deforestation in the southern Peruvian Amazon (Hotspot C). An important study found that gold mining cleared around 123,550 acres up through 2012.9 We built off this work, and by analyzing hundreds of high resolution imageres, found that gold mining caused the loss of an additional 30,890 acres between 2013 and 2016 (MAAP #50). Thus, gold mining is thus far responsible for the total loss of around 154,440 acres in southern Peru. Much of the most recent deforestation is illegal due to its occurrence in protected areas and buffer zones strictly off-limits to mining activities.

Most notably, we have closely tracked the illegal gold mining invasion of Tambopata National Reserve, an important protected area in the Madre de Dios region with renowned biodiversity and ecotourism. The initial invasion occurred in November 2015 (MAAP #21), and has steadily expanded to over 1,110 acres (MAAP #24, MAAP #30, MAAP #46). As part of this invasion, miners have modified the natural course of the Malinowski River, which forms the natural northern border of the reserve (MAAP #33). In addition, illegal gold mining deforestation continues to expand within the reserve’s buffer zone, particularly in an area known as La Pampa (MAAP #12, MAAP #31).

Further upstream, illegal gold mining is also expanding on the upper Malinowski River, within the buffer zone of Bahuaja Sonene National Park (MAAP #19, MAAP #43).

In contrast to the escalating situation in Tambopata, we also documented that gold mining deforestation has been contained in the nearby Amarakaeri Communal Reserve, an important protected area that is co-managed by indigenous communities and Peru’s national protected areas agency. Following an initial invasion of 27 acres in 2014 and early 2015, satellite imagery shows that management efforts have prevented any subsequent expansion within the protected area (MAAP #6, MAAP #44).

In addition to the above cases in Madre de Dios, gold mining deforestation is also increasingly an issue in the adjacent regions of Cusco and Puno (MAAP #14).

There are several small, but potentially emerging, gold mining frontiers in the central and northern Peruvian Amazon (MAAP #49). The Peruvian government has been working to contain the illegal gold mining in the El Sira Communal Reserve (MAAP #45). Further north in Amazonas region, there is gold mining deforestation along the Rio Santiago (MAAP #36, MAAP #49), and in the remote Condor mountain range along the border with Ecuador (MAAP #49).

Roads

Roads are a well-documented driver of deforestation in the Amazon, particularly due to their ability to facilitate human access to previously remote areas.10 Roads often serve as an indirect driver, as most of the deforestation directly associated with agriculture, cattle pasture, and gold mining is likely greatly facilitated by proximity to roads. We documented the start of a controversial road construction project that would cut through the buffer zones of two important protected areas, Amarakaeri Communal Reserve and Manu National Park (MAAP #29).

Logging Roads

In relation to general roads described above, we distinguish access roads that are constructed to gain entry to a particular project. The most notable type of access roads in Peru are logging roads, which are likely a leading cause of forest degradation as they facilitate selective logging of valuable timber species in remote areas.

One of the major recent advances in forest monitoring is the ability to quickly identify the construction of new logging roads. The unique linear pattern of these roads appears quite clearly in Landsat-based tree cover loss alerts such as GLAD and CLASlite. This advance is important because it is difficult to detect illegal logging in satellite imagery because loggers in the Amazon often selectively cut high value species and do not produce large clearings. But now, although it remains difficult to detect the actual selective logging, we can detect the roads that indicate that selective logging is taking place in that area.

In a series of articles, we highlighted the recent expansion of logging roads, including the construction of 1,134 km between 2013 and 2015 in the central Peruvian Amazon (MAAP #3, MAAP #18). Approximately one-third of these roads were within the buffer zones of Cordillera Azul and Sierra del Divisor National Parks (MAAP #15).

We documented the construction of an additional 83 km of logging roads during 2016,  (MAAP #40, MAAP #43) including deeper into the buffer zone of Cordillera Azul National Park.

Another major finding is the rapid construction of the logging roads. In several cases, we documented the construction rate of nearly five kilometers per week (MAAP #18, MAAP #40, MAAP #43).

Determining the legality of these logging roads is complex, partly because of the numerous national and local government agencies involved in the authorization process. Many of these roads are near logging concessions and native communities, whom may have obtained the rights for logging from the relevant forestry authority (in many cases, the regional government).

Coca

According to a recent United Nations report, the Peruvian land area under coca cultivation in 2015 (99,580 acres) was the lowest on record (since 2001) and part of a declining trend since 2011 (154,440 acres).11 There are 13 major coca growing zones in Peru, but it appears that only a few of them are actively causing new deforestation. Most important are two coca zonas in the region of Puno that are causing deforestation within and around Bahuaja Sonene National Park (MAAP #10, MAAP #14). Several coca zones in the regions of Cusco and Loreto may also be causing some new deforestation.

Hydroelectric Dams

Although there is a large portfolio of potential new hydroelectric dam projects in the Peruvian Amazon,12 many of not advanced to implementation phase. Thus, forest loss due to hydroelectric dams is not currently a major issue, but this could quickly change in the future if these projects are revived. For example, in adjacent western Brazil, we documented the forest loss of 89,205 acres associated with the flooding caused by two dams on the upper Madeira River (MAAP #34).

Hydrocarbon (Oil & Gas)

During the course of our monitoring, we have not yet detected major deforestation events linked to hydrocarbon-related activities. As with dams, this could change in the future if oil and gas prices rise and numerous projects in remote corners of the Amazon move forward.

Methodology

MAAP methodology has 4 major components:

  1. Forest Loss Detection. MAAP reports rely heavily on early-warning tree cover loss alerts to help us identify where new deforestation is happening. Currently, our primary tool is GLAD alerts, which are developed by the University of Maryland and Google,13 and presented by WRI’s Global Forest Watch and Peru’s GeoBosques. These alerts, launched in Peru in early 2016, are based on 30-meter resolution Landsat satellite images and updated weekly. We also occasionally incorporate CLASlite, forest loss detection software based on Landsat (and now Sentinel-2) developed by the Carnegie Institution for Science, and the moderate resolution (250 meters) Terra-i alerts. We are also experimenting with Sentinel-1 radar data (freely available from the European Space Agency), which has the advantage of piercing through cloud cover in order to continue monitoring despite persistent cloudy conditions
  2. Prioritize Big Data. The early warning systems noted above yield thousands of alerts, thus a procedure to prioritize the raw data is needed. We employ numerous prioritization methods, such as creation of hotspot maps (see below), focus on key areas (such as protected areas, indigenous territories, and forestry concessions), and identification of striking patterns (such as linear features or large-scale clearings).
  1. Identify Deforestation Drivers. Once priority areas are identified, the next challenge is to understand the cause of the forest loss. Indeed, one of the major advances of MAAP over the past year has been using high-resolution satellite imagery to identify key deforestation drivers. Our ability to identify these deforestation drivers has been greatly enhanced thanks to access to high-resolution satellite imagery provided by Planet 14
    (via their Ambassador Program) and Digital Globe (via the NextView Program, courtesy of an agreement with USAID). We also occasionally purchase imagery from Airbus(viaApollo Mapping).
  2. Publish User-Friendly Reports. The final step is to publish technical, but accessible, articles highlighting novel and important findings on the MAAP web portal. These articles feature concise text and easy-to-understand graphics aimed at a wide audience, including policy makers, civil society, researchers, students, journalists, and the public at large. During preparation of these articles, we consult with Peruvian civil society and relevant government agencies in order to improve the quality of the information.

Endnotes

MINAM-Peru (2016) Estrategia Nacional sobre Bosques y Cambio Climático.

Methodology: Kernel Density tool from Spatial Analyst Tool Box of ArcGis. The 2016 data is based on GLAD alerts, while the 2012-15 data is based on official annual forest loss data

Ravikumar et al (2016) Is small-scale agriculture really the main driver of deforestation in the Peruvian Amazon? Moving beyond the prevailing narrative. Conserv. Lett. doi:10.1111/conl.12264

4 Gutiérrez-Vélez VH et al (2011). High-yield oil palm expansion spares land at the expense of forests in the Peruvian Amazon. Environ. Res. Lett., 6, 044029.

Environmental Investigation Agency EIA (2015) Deforestation by Definition.

NG J (2015) United Cacao replicates Southeast Asia’splantation model in Peru, says CEO Melka. The Edge Singapore, July 13, 2015.

Palmas del Shanusi & Palmas del Oriente; http://www.palmas.com.pe/palmas/el-grupo/empresas

Hill D (2015) Palm oil firms in Peru plan to clear 23,000 hectares of primary forest. The Guardian, March 7, 2015.

Asner GP, Llactayo W, Tupayachi R,  Ráez Luna E (2013) Elevated rates of gold mining in the Amazon revealed through high-resolution monitoring. PNAS 46: 18454. They reported 46,417 hectares confirmed and 3,268 hectares suspected (49,865 ha total).

10 Laurance et al (2014) A global strategy for road building. Nature 513:229; Barber et al (2014) Roads, deforestation, and the mitigating effect of protected areas in the Amazon.  Biol Cons 177:203.

11 UNODC/DEVIDA (2016) Perú – Monitoreo de Cultivos de Coca 2015.

12 Finer M, Jenkins CN (2012) Proliferation of Hydroelectric Dams in the Andean Amazon and Implications for Andes-Amazon Connectivity. PLoS ONE 7(4): e35126.

13 Hansen MC et al (2016) Humid tropical forest disturbance alerts using Landsat data. Environ Res Lett 11: 034008.

14 Planet Team (2017). Planet Application Program Interface: In Space for Life on Earth. San Francisco, CA. https://api.planet.com

Citation

Finer M, Novoa S (2017) Patterns and Drivers of Deforestation in the Peruvian Amazon. MAAP: Synthesis #2.

MAAP #20: New Airstrip in Coca-growing Area within Bahuaja Sonene National Park (Puno, Peru)

MAAP #10 detailed the extensive deforestation between 2000 and 2014 (538 hectares or 1,329 acres) in the Colorado sector of Bahuaja Sonene National Park, an important protected area in the southern Peruvian Amazon. Additionally, we described how this sector has a high density of coca plantations, one of the main drivers of the observed deforestation. Coca has many traditional uses in Andean cultures, but is also used to produce cocaine.

Here in MAAP #20, we show that in 2015 the deforestation has continued in this sector of the park. Moreover, as seen in Image 20a, we detected the construction of a new airstrip in a nearby remote area part of the park that is likely being used for transporting coca.

Image 21a. High-resolution view of the area designated for a landing strip, inside Bahuaja Sonene National Park. See Zoom A in Image 21c for context. Data: WorldView-2 of Digital Globe (NextView).
Image 20a. High-resolution view of the area designated for a landing strip, inside Bahuaja Sonene National Park. See Zoom A in Image 20c for context. Data: WorldView-2 of Digital Globe (NextView).

Airstrip

Image 20a shows a high-resolution (0.5 m) image of the new airstrip, which is 580 meters long and 8 meters wide (in addition, see Zoom A in Image 20c for context). It is characteristic of an airstrip designed for a single-engine plane.  As seen in Image 20b, the airstrip was constructed between May and June 2015. In addition, Image 20c, shows that the airstrip is located within the zones of strict and wildlife protection. It appears that a previous airstrip was constructed in this same area in 2013, but became overgrown 2014. It is worth noting that there are no native communities in this area.

Image 21b. Comparison of these two Landsat images from 2015 shows the area that has been designated as an airplane landing strip. Data: USGS.
Image 20b. Comparison of these two Landsat images from 2015 shows the area that has been designated as an airplane landing strip. Data: USGS.

Reference Map

Image 20c shows the reference map for this article. It shows the Colorado sector of Bahuaja Sonene National Park. Zoom A corresponds to the airstrip described above, while Zoom B corresponds to the new deforestation analysis described below.

Image 21c. Deforestation detected inside the Colorado zone of Bahuaja Sonene National Park. Data: SERNANP, MINAM/PNCB, CLASlite, USGS, WCS.
Image 20c. Deforestation detected inside the Colorado zone of Bahuaja Sonene National Park. Data: SERNANP, MINAM/PNCB, CLASlite, USGS, WCS.

New Deforested Areas associated with Coca Cultivation

Image 20d shows a comparison of two high-resolution images showing the deforestation of 40 hectares (99 acres) between October 2014 (left panel) and October 2015 (right panel). The yellow dashed circles indicate the newly deforested areas, which are near previous coca plantations. In addition, Image 20c shows that these newly deforested areas are located within the zones of strict and wildlife protection.

Imagen 20d. Zoom “B” mostrando nuevas áreas deforestadas en dos imágenes de alta resolución. Fuentes: SPOT, WorldView-2 de Digital Globe (NextView).
Image 20d. Zoom “B” shows newly deforested areas in two high-resolution images. Data: SPOT, WorldView-2 of Digital Globe (NextView).

Citation

Novoa S, Finer M (2015) New Airstrip in Coca-growing Area within Bahuaja Sonene National Park (Puno, Peru). MAAP: 20.

MAAP Synthesis #1: Patterns and Drivers of Deforestation in the Peruvian Amazon

We present a preliminary analysis of current patterns and drivers of deforestation in the Peruvian Amazon. This analysis is largely based on the first 15 articles published on MAAP between April and September 2015, but also incorporates information from other relevant sources. We describe this analysis as preliminary because as MAAP research continues, we will be able to improve and refine our synthesis in subsequent editions.

MAAP_Synthe_Sa_v4_en
Image S1a. Recent patterns and drivers of deforestation in the Peruvian Amazon. Numbers indicate relevant MAAP article. Data: SERNANP, IBC, MINAM-PNCB/MINAGRI-SERFOR, MAAP.

Introduction & Summary of Key Results

Image S1a illustrates recent (2000 – 2013) patterns of deforestation in the Peruvian Amazon based on data from the Peruvian Ministries of Environment[i] and Agriculture[ii]. These two Ministries have documented a total forest loss of around 1.65 million hectares (ha) in the Peruvian Amazon between 2001 and 2014, with an increasing trend in recent years (2014 had the highest forest loss on record with 177,571 ha)[iii],[iv]. Another recent report by the Peruvian government stated that the majority (75%) of the Amazonian deforestation is due to small-scale clearings related to agriculture and livestock activities, usually near roads or rivers[v].

Building off of that historical and annual information, our goal at MAAP is to monitor deforestation in near real-time. Since April 2015, we have published numerous articles analyzing areas in the northern, central, and southern Peruvian Amazon. In this initial analysis, we have found that three of the most important drivers of deforestation are large-scale oil palm (and cacao) plantations, gold mining, and coca cultivation. We also found a growing network of logging roads that contribute to forest degradation. Image S1a displays the general geographic distribution of these drivers of deforestation and degradation.

We estimate that around 30,000 hectares of primary forest was cleared since 2000 for large-scale oil palm and cacao plantations. Cacao has recently joined oil palm as a deforestation driver due to the arrival of the company United Cacao and their implementation of the large-scale agro-industrial model in place of traditional small-scale plantations on previously degraded lands.

Gold mining has directly caused the deforestation of over 43,000 ha since 2000, mostly in the region of Madre de Dios. In recent years, this deforestation has been concentrated in the Tambopata National Reserve buffer zone.

Although coca cultivation is reportedly declining in Peru, we found that it remains a major driver of deforestation, particularly within and around remote protected areas. For example, we documented 143 ha of coca related deforestation within the Sierra del Divisor Reserved Zone, and an additional 2,638 ha related to shifting agricultural cultivation, which includes coca, within and around Bahuaja Sonene National Park.

We also documented a recent expansion of logging roads in the central Peruvian Amazon. This finding is significant because it is difficult to detect selective logging in satellite imagery, but now we can at least detect the roads that indicate that selective logging is taking place in a given area.

We identified some important geographic patterns related to the four drivers described above. For example, large-scale oil palm (and cacao) are concentrated in the northern Peruvian Amazon, while gold mining deforestation has largely been in the south. Coca-driven deforestation appears to be particularly problematic in the southern Peruvian Amazon, but also exists in the north. The construction of new logging roads is currently most active in the central Peruvian Amazon.

The documented deforestation is caused by both illegal and legal means. For the former, there is extensive deforestation from illegal gold mining and coca cultivation. Regarding the latter, oil palm and cacao companies are exploiting loopholes in the Peruvian legal framework that facilitate large-scale deforestation for agricultural projects.

Large-scale Agriculture (Oil Palm and Cacao)

MAAP_Synthe_Sb_v4_en
Image S1b. Large-scale agriculture deforestation in the northern Peruvian Amazon. Numbers indicate relevant MAAP article. Data: SERNANP, IBC, MINAM-PNCB/MINAGRI-SERFOR, MAAP.

Image S1b illustrates that large-scale agriculture (namely oil palm and cacao) is an important cause of deforestation in northern Peru.

Importantly, several oil palm and cacao companies are changing the production model in Peru from small-scale to large-scale agro-industrial. For example, in a recent interview, United Cacao CEO Dennis Melka stated that his company is trying to replicate the agro-industrial model used by oil palm companies in Southeast Asia[vi].

This shift is noteworthy because large-scale plantations usually come at the expense of forests, while small-scale plantations are better able to take advantage of previously cleared lands[vii]. We estimate that over 30,000 hectares of primary forest was cleared since 2000 for large-scale oil palm and cacao plantations (see below). Much less primary forest, around 575 ha, was cleared for small-scale oil palm (we have yet to evaluate small-scale cacao).

Note that we emphasize the clearing of primary forest. We conducted an additional analysis to determine whether oil palm (both small and large-scale) and cacao (just large-scale) plantations were originally sited on lands with primary forest, secondary forest, or already deforested. We defined primary forest as an area that from the earliest available Landsat, in this case 1990, was characterized by dense closed canopy forest cover.

The following is a concise breakdown of how we calculated the 30,000 ha of primary forest loss from large-scale plantations.

MAAP articles #2, #9, and #13 demonstrated that 2,276 ha of primary forest was cleared by United Cacao between May 2013 and September 2015 outside of the town of Tamshiyacu in the northern Peruvian Amazon (Loreto region).

MAAP article #4 detailed the deforestation of 9,400 ha of primary forest (plus an additional 2,350 ha of secondary forest) between 2011 and 2015 for two large-scale oil palm projects near the town of Nueva Requena in the central Peruvian Amazon (Department of Ucayali).

In addition, yet unpublished MAAP analysis shows that in Palmas de Shanusi/Oriente (oil palm projects operated by the company Grupo Palmas), 6,974 ha of primary forest were cleared between 2006 and 2011, although the legally mandated 30% forest cover reserves were maintained. An additional 8,225 ha of primary forest was cleared in areas immediately surrounding the concessions.

Finally, although not yet published on MAAP, we also documented nearly 3,500 ha of primary forest loss in other large-scale oil palm projects in San Martin and Ucayali regions.

It is important to emphasize that several oil palm and cacao companies are exploiting various loopholes in the Peruvian legal framework that facilitate large-scale deforestation for agricultural projects[viii]. In fact, these companies argue that according to Peruvian law, they are engaged in legal “forest clearing”, not illegal “deforestation”[ix].

Gold Mining

MAAP_Synthe_Sc_v4_en
Image S1c. Gold mining deforestation in the Peruvian Amazon. Numbers indicate relevant MAAP article. Data: SERNANP, IBC, MINAM-PNCB/MINAGRI-SERFOR, MAAP.

Image S1c illustrates that gold mining-driven deforestation is largely concentrated in the southern Peruvian Amazon, particularly in the region of Madre de Dios and adjacent Cusco.

According to the scientific literature, gold mining deforestation in Madre de Dios increased from 10,000 ha in 2000 to 50,000 ha in 2012[x]. MAAP articles #1, #5, and #12 documented the deforestation of an additional 2,774 ha between 2013 and 2015 in two gold mining hotspots (La Pampa and Upper Malinowski), both of which are located within the buffer zone of the Tambopata National Reserve. In addition, MAAP #6 showed gold mining deforestation expanding from another Madre de Dios gold mining hotspot (Huepetuhe) into the tip of Amarakaeri Communal Reserve (11 ha).

Much of the Madre de Dios gold mining deforestation described above is illegal because it is occurring within and around protected areas where mining is not permitted under the government-led formalization process.

MAAP articles #6 and #14 detailed recent gold mining deforestation in the region of Cusco. Specifically, we documented the deforestation of 967 ha along the Nuciniscato River and its major tributaries since 2000 (with the vast majority occurring since 2010). Much of this deforestation appears to be linked to gold mining.

Thus, the total documented gold mining deforestation in Madre de Dios and adjacent Cusco is at least 53,750 ha[xi], over 80% of which has occurred since 2000. This total is an underestimate since we have not yet done detailed studies for 2013 – 2015 deforestation in all of the known gold mining zones in these two regions.

In addition, MAAP #7 showed two gold mining zones in the region of Ucayali (along the Sheshea and Abujao Rivers, respectively). Much of this deforestation occurred between 2000 and 2012.

Finally, there are also reports of extensive gold mining in northern Peru (the regions of Amazonas and Loreto) but we do not yet have data showing that it is causing deforestation.

Coca

MAAP_Synthe_Sd_v4_en
Image S1d. Coca cultivation areas in the Peruvian Amazon. Numbers indicate relevant MAAP article. Data: UNODC 2014, MINAM-PNCB/MINAGRI-SERFOR, SERNANP, NatureServe.

Although the most recent report from the United Nations Office on Drugs and Crime (UNODC) indicates that overall coca cultivation is declining in Peru[xii], our research finds that it remains a major driver of deforestation in certain areas, particularly within and around several remote protected areas.

Image S1d displays the distribution of current coca-cultivation areas (in relation to protected areas) based on the data from the latest United Nations report. Of these areas, we have thus far focused on the three detailed below.

MAAP articles #7 and #8 show recent coca-related deforestation within the southern section of the Sierra del Divisor Reserved Zone. This area is particularly important because it is soon slated to be upgraded to a national park. Specifically, we documented coca-related deforestation of 130 ha between 2013 and 2014 within the southwestern section of the reserve, and, most recently, a new plantation of 13 ha during June 2015 within the southeast section.

MAAP article #10 revealed that shifting agricultural cultivation, that includes coca, is also a major issue within and around Bahuaja Sonene National Park, located in the southern Peruvian Amazon. Specifically, we found the recent deforestation of 538 hectares within the southern section of the Park, and an additional 2,100 hectares in the surrounding buffer zone. Much of this deforestation is likely linked to coca cultivation since the latest United Nations report indicates these areas contain high coca plantation densities.

MAAP article #14 documents the deforestation of 477 ha along the Nojonunta River in Cusco since 2000 (with a major peak since 2010). Much of this deforestation is likely linked to coca cultivation since the latest United Nations report indicates these areas contain medium to high coca plantation densities. 

Logging Roads

MAAP_Synthe_Se_v4_en
Image S1e. Logging roads in the Peruvian Amazon. Numbers indicate relevant MAAP article. Data: SERNANP, IBC, MINAM-PNCB/MINAGRI-SERFOR, MINAGRI, MAAP.

One of the major advances discovered in this work is the ability to identify the expansion of new logging roads. This advance is important because it is extremely difficult to detect illegal logging in satellite imagery because loggers in the Amazon often selectively cut high value species and do not produce large clearings. But now, although it remains difficult to detect the actual selective logging, we can detect the roads that indicate that selective logging is taking place in that area.

Image S1e illustrates the likely logging roads that we have recently detected. Of these areas, we have thus far focused on the two detailed below.

MAAP article #3 shows the rapid proliferation of two new road networks in the northern Peruvian Amazon (Loreto region). Most notably, it highlights the construction of 148 km of new roads, possibly illegal logging roads, through mostly primary forest between 2013 and 2014. One of the roads is within the buffer zone of the Cordillera Azul National Park.

In addition, MAAP article #7 shows the expansion of new logging roads near both the southern and northwestern sections of the Sierra del Divisor Reserved Zone. In both cases, the expansion is very recent (between 2013 and 2015).

 

[i] National Program of Forest Conservation for the Mitigation of Climate Change – PNCB.

[ii] Servicio Nacional Forestal y de Fauna Silvestre – SERFOR

[iii] MINAGRI-SERFOR/MINAM-PNCB (2015) Compartiendo una visión para la prevención, control y sanción de la deforestación y tala ilegal.

[iv] Note that some of the documented forest loss may come from natural causes, such as landslides or meandering rivers.

[v] MINAM (2013) Fondo Cooperativo Para El Carbono de los Bosques (FCPF) Plantilla de Propuesta para la Fase de Preparación para REDD+ (Readiness Plan Proposal – RPP). Link: http://www.minam.gob.pe/cambioclimatico/wp-content/uploads/sites/11/2014/03/R-PP-Per%C3%BA-Final-Dec-2013-RESALTADO_FINAL_PUBLICADA-FCPF_24-febrero.pdf

[vi] NF Joan (2015) United Cacao replicates Southeast Asia’s plantation model in Peru, says CEO Melka. The Edge Singapore.Link: http://www.unitedcacao.com/images/media-articles/20150713-the-edge-united-cacao.pdf

[vii] Gutiérrez-Vélez VH, DeFries R, Pinedo-Vásquez M, et al. (2011) High-yield oil palm expansion spares land at the expense of forests in the Peruvian Amazon. Environ. Res. Lett., 6, 044029. Link: http://iopscience.iop.org/article/10.1088/1748-9326/6/4/044029/pdf

[viii] Environmental Investigation Agency (2015) Deforestation by Definition. Washington, DC. Link: http://eia-global.org/news-media/deforestation-by-definition

[ix] Tello Pereyra R (2015) Situacion legal, judicial, y administrativa de  Cacao del Peru Norte SAC. Link: https://www.youtube.com/watch?v=p_YIe70u1oA

[x] Asner GP, Llactayo W, Tupayachia R, Ráez Luna E (2013) PNAS 110 (46) 18454-18459. Link: http://www.pnas.org/content/110/46/18454.abstract

[xi] That is, 50,000 ha from the literature and 3,750 ha from MAAP analysis.

[xii] UNODC (2015) Monitoreo de cultivos ilícitos Perú 2014. Link: https://www.unodc.org/documents/crop-monitoring/Peru/Peru_Informe_monitoreo_coca_2014_web.pdf

Citation

Finer M, Novoa S (2015) Patterns and Drivers of Deforestation in the Peruvian Amazon. MAAP Synthesis #1. Link: https://www.maapprogram.org/2015/09/maap-synthesis1/

Image #14: Cusco – Increasing Deforestation Driven by Coca and Gold Mining

In MAAP #14 we take our first detailed look at the region of Cusco. The city of Cusco is of course well known as the former capital of the Inca empire and current gateway to Machu Picchu, but the greater Cusco region is a vast area including large tracts of Amazon forest. Here, we focus on the eastern Cusco region, an area that is experiencing increasing deforestation from gold mining and coca cultivation.

Cusco_MAAP_12a_v4
Image 14a. Recent deforestation patterns in northeast Cusco region. Data: PNCB, USGS, SERNANP, IBC.

Key Results

We highlight two major expanding deforestation zones in the eastern Cusco region. Both zones are along major tributaries of the Araza River, which itself is a tributary of the Inambari River.

1) Nuciniscato River (see Zoom A). We documented a major deforestation spike since 2010 along this river and its major tributaries. Since 2010, there has been deforestation of 764 ha, much of which appears to be related to gold mining.

2) Nojonunta River (see Zoom B). We document a recent (2014) deforestation surge in this area, much of which appears to be related to coca cultivation.

Data Description

In the following maps:

Any variation of green in the satellite imagery indicates areas of forest cover.

Yellow (2000-2004), orange (2005-2008), red (2009-2012), and purple (2013) indicate areas that were deforested between 2000 and 2013 according to data from the National Program of Forest Conservation for the Mitigation of Climate Change (PNCB) of the Ministry of the Environment of Peru.

The colors pink (2014) and turquoise (2015) indicate areas that were deforested in the last two years based on our analysis of Landsat imagery using CLASlite forest monitoring software.

Zoom A: Nuciniscato River

Cusco_MAAP_12b_v3
Image 14b. Zoom A (see Image 12a for context). Data: PNCB, USGS, SERNANP, IBC.

We documented the deforestation of 967 ha along the Nuciniscato River and its major tributaries since 2000. Image 14b shows that the vast majority (79% or 764 ha) of this deforestation has occurred since 2010. Peak deforestation occurred in 2012 (219 ha) and dipped slightly in 2014 (115 ha).

As noted in MAAP #6, part of this deforestation (along the upper Nuciniscato River) is entering the buffer zone of the Amarakaeri Communal Reserve.

Zooms A1 and A2: Examples of Deforestation in 2015

To better understand the principal deforestation drivers along the Nuciniscato River, we acquired high resolution satellite imagery. Much of the recent deforestation since 2010 is characteristic of gold mining: along river courses with forest clearing, earth removal, and waste-water lagoons. Images 14c and 14d both show very recent deforestation (between February and August 2015) with these characteristics.

Cusco_MAAP_12c_v5_m
Image 14c. Zoom A1 (see Image 14b for context). Data: SPOT 7 from Airbus, GeoEye from Digital Globe (NextView).
Cusco_MAAP_12d_v5_m
Image 14d. Zoom A2 (see Image 14b for context). Data: SPOT 7 from Airbus, GeoEye from Digital Globe (NextView).

Zoom B: Nojonunta River

Cusco_MAAP_12e_v3
Image 14e. Zoom B (see Image 21a for context). Data: PNCB, USGS.

We documented the deforestation of 477 ha along the Nojonunta River since 2000. Image 14e shows that the vast majority (85% or 403 ha) of this deforestation has occurred since 2010. Peak deforestation occurred in 2014 (207 ha), particularly in the upper Nojonunta.

Zoom B1: Deforestation Driven by Coca Cultivation

Cusco_MAAP_12f_v2_m
Image 14f. Zoom B1. Data: SPOT 7 from Airbus, UNODC 2014.

In the recent UNODC (United Nations Office on Drugs and Crime) report “Monitoreo de Cultivos de Coca 2014” [Coca Crop Monitoring 2014], it was reported that the area around the Nojonunta River (coca zone San Gabán) has a medium to high density of coca cultivation.

Image 14f displays the UNODC coca density data (left panel) in relation to a recent high resolution satellite image of the area (right panel). Thus, the data indicates that coca cultivation is a major driver of the deforestation detected in this case.

Citation

Finer M, Novoa S (2015) Increasing deforestation in Northeast Cusco region from coca and gold mining. MAAP: Image #14. Link: https://www.maapprogram.org/2015/09/image-14-cusco/

Image #10: Bahuaja Sonene National Park – Increasing Deforestation Within and Around Southern Section (Puno, Peru)

Here, in MAAP #10, we show the results of a deforestation analysis of two sectors of Bahuaja Sonene National Park and its surrounding buffer zone. The Park, which covers an area of more than 1.6 million hectares in the regions of Puno and Madre de Dios in the southern Peruvian Amazon, is an area of high biological diversity.

Specifically, we found increasing deforestation in 1) the buffer zone of the Park’s western section (Loromayo sector) and 2) inside the Park’s southeastern section (Colorado sector). In both cases, we identified shifting cultivation associated with coca cultivation as one of the main drivers of deforestation.

Bahuaja_Sonene_MAAP_10a_v3_e (1)
Image 10a. Deforestation detected in and around Bahuaja Sonene National Park and its buffer zone. Please note that Zooms “A” and “B” are described in more detail below. Data: SERNANP, PNCB, USGS.

Key Results

We highlight two key areas within and around Bahuaja Sonene National Park where deforestation grew substantially between 2013 and 2015:

1) Sector Loromayo, located in the buffer zone immediately outside the western section of the Park (see Zoom A). We estimate that more than 1,000 hectares (ha) were deforested since 2010, peaking in 2014 (331 ha). This expanding deforestation entered the Park in 2014.

2) Sector Colorado, located in the southeastern section of the Park (see Zoom B). We estimate, between 2001 to 2014, the deforestation of over 530 hectares inside the Park and over 1,170 hectares in the surrounding buffer zone. As in Loromayo, there was a notable increase in deforestation starting in 2010, with the peak occurring in 2014.

In both sectors, Loromayo and Colorado, we identified that one of the main drivers of deforestation is coca cultivation.

Description of Data

In the following maps:

Any variation of green in the satellite imagery indicates areas of forest cover.

Yellow (2000-2004), orange (2005-2008), red (2009-2012), and purple (2013) indicate areas that were deforested between 2000 and 2013 according to data from the National Program of Forest Conservation for the Mitigation of Climate Change (PNCB) of the Ministry of the Environment of Peru.

The colors pink (2014) and turquoise (2015) indicate areas that were deforested in the last two years based on our analysis of Landsat imagery using CLASlite forest monitoring software.

Zoom A: Loromayo River (western buffer zone)

Bahuaja_Sonene_MAAP_10c_v3_e
Image 10b. The expansion of deforestation along the Loromayo river in the buffer zone to the west of Bahuaja Sonene National Park. Data: SERNANP, USGS, IBC, PNCB.

As shown in Figure 10b, we identified a striking pattern of deforestation in the sector Loromayo, located between the Malinowski and Chaspa rivers in the Park’s western buffer zone in the department of Puno. Note that the deforestation entered the Park in 2014.

In this area, we documented the deforestation of 1,005 hectares since 2010. This deforestation peaked in 2014, with 331 hectares, including 1.8 hectares within the Park. Not much data is yet available for 2015.

Please note that we previously reported on the advance of gold mining deforestation seen in Image 10b along the Malinowski River in MAAP #5.

Sector Loromayo: Shifting Agriculture that includes Coca Cultivation

Bahuaja_Sonene_MAAP_10g_v3_m_e
Image 10c. Coca density data (upper panel) in relation to a recent high resolution satellite image of the area (lower panel). Data: UNODC 2014, SERNANP, Worldview-2 from Digital Globe (NextView).

In the recent UNODC (United Nations Office on Drugs and Crime) report “Monitoreo de Cultivos de Coca 2014” [Coca Crop Monitoring 2014], it was reported that the Loromayo sector (coca zone San Gabán) has a medium to high density of coca cultivation, with a recent increase of 5.9% since 2013. Therefore, we conculde that coca cultivation is one of the major drivers of the observed deforestation.

Image 10c displays the most recent UNODC coca density data (upper panel) in relation to a recent high resolution satellite image of the area (lower panel). Deforestation is rapidly expanding in the vicinity of the Park boundary. Unfortunately, in this image, a few clouds cover the small area where the deforestation recently entered Park.

Zoom B: Sector Colorado (Southeastern section of Park)

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Image 10d. The expansion of deforestation in the Colorado sector of Bahuaja Sonene National Park. Data: SERNANP, USGS, IBC, PNCB.

As seen in Figure 10d, deforestation is well established and increasing in the sector Colorado, located in the southeast section of Bahuaja Sonene National Park, with the Region of Puno. Our analysis in this area extended from the upper Tambopata River to the Azata river.

We document the deforestation, since 2001, of 538 ha inside the Park and an additional 1,172 ha within the surrounding buffer zone. Similar to the sector Loromayo sector, there was a marked increase in deforestation since 2010, with a peak in 2014. More than half of the deforestation (53%, 287 ha) occurred since 2010, with a maximum of 81 ha in 2014. Not much data is yet available for 2015.

Sector Colorado: Presence of Coca Cultivation Inside the Park

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Image 10e. Coca density data (upper panel) in relation to a recent high resolution satellite image of the area (lower panel). Data: UNODC 2014, SERNANP, SPOT6 from Airbus.

According to a recent report by the Wildlife Conservation Society (WCS), the deforestation in the Colorado sector was a result of the advance of agriculture and livestock cultivation in the area. Moreover, according to the recent UNODC  report noted above, this sector (coca zone Inambari-Tambopata) also has a high density of coca, with 108 ha on the interior of Bahuaja Sonene National Park and 1,610 ha in the buffer zone, likely making it one of the major drivers of the observed deforestation.

Image 10e displays the UNODC coca density data (upper panel) in relation to a recent high resolution satellite image of the area (lower panel).

SERNANP Response

In response to this article, SERNANP (the Peruvian protected areas agency) issued this statement:

“El sector denominado como Colorado es sector ubicado dentro del Parque Nacional Bahuaja Sonene, que actualmente se encuentra zonificado como Zona de Recuperación;  dicha zonificación se otorga a aquellas zonas que por actividades antrópicas han sido afectadas y que necesitan estudios complementarios para determinar su zonificación definitiva.”

[The sector named ‘Colorado’ is a sector located within the Bahuaja Sonene National Park, which currently is zoned as a ‘Restoration Zone.’  Said zoning is extended to those zones which have been affected due to anthropic activities and require supplementary studies so as to determine their definitive zoning designation.]

Debemos señalar que en este sector se han detectado severas plagas que afectan los cultivos de frutos como la naranja y café, desencadenando que la población asentada en la zona de amortiguamiento del Parque se vean forzada a reemplazar estas plantaciones por el cultivo de coca en algunos casos.

[We should note that severe pests have been detected in this sector which affect the cultivation of fruit such as oranges and coffee; this has lead the population settled in the park’s buffer zone to have no choice but to replace these crops with the cultivation of coca in some cases.]

Esta situación ha sido identificada y advertida oportunamente por el jefe del Parque Nacional Bahuaja Sonene a las entidades pertinentes para iniciar su erradicación; no obstante, el SERNANP también ha emprendido un trabajo conjunto con las autoridades locales y el comité de gestión del área natural protegida para combatir esta amenaza, lo cual figura en el Plan Maestro 2015-2019 del área en mención. Ahí se contemplan estrategias  como la construcción de un puesto de control y vigilancia para monitorear permanentemente esta situación.

[The head of the Bahuaja Sonene National Park has identified and issued a warning about this situation in a timely manner to the relevant entities so as to initiate its eradication work; notwithstanding, SERNANP has also undertaken joint work with local authorities and the management committee of the natural protected area to combat this threat, which figures in the 2015-2019 Master Plan of the area in question.  The latter contains strategies such as the construction of a checkpoint and guard post for permanently monitoring this situation.]

Asimismo, se vienen promoviendo mesas de diálogo y el desarrollo de actividades económicas sostenibles que reemplacen los cultivos ilícitos y que garanticen la calidad de vida de la población de Colorado.”

[Likewise, dialogue roundtables and the development of sustainable economic activities have been promoted that can replace the illicit crops and guarantee quality of life for the population of Colorado.]

Citation

Finer M, Novoa S (2015) Bahuaja Sonene National Park – Increasing Deforestation Within and Around the Southern Section (Puno, Peru). MAAP: Image #10. Link: https://www.maapprogram.org/2015/07/image-10-bahuaja/

References

UNODC. Monitoreo de cultivos ilícitos Perú 2014. p 29. (Lima, 2015).

Image #8: New Deforestation Detected Within Sierra del Divisor (Peru) in June

Recall that in Image of the Week #7 we documented the increasing threats (illegal coca, logging, and mining) to the Sierra del Divisor Reserved Zone. We just obtained brand new, high-resolution imagery showing new deforestation deep within this protected area during the month of June. Here, Image of the Week #8, presents new maps of this recent deforestation. According to several consulted experts, the cause of this deforestation is illegal coca cultivation or a new illegal logging camp.

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Image 8a: Very high resolution (38 cm) image from June 23 showing new deforestation within the Sierra del Divisor Reserved Zone. Data: WorldView-3 from Digital Globe (NextView).

New Deforestation Detected

Image 8a shows the new deforestation detected within the southeast section of the Sierra del Divisor Reserved Zone. As of June 23, 2015 (the date of the image), the total new deforestation was 13 hectares. This deforestion is located between the La Cúpula and Shesha hills.

In Image of the Week #7 we showed that there is a series of illegal logging camps nearby, but this new deforestation is located much deeper in the reserve. According to several consulted experts, the cause of the new deforestation is illegal coca cultivation or a new illegal logging camp.

Updated Baseline Map

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Image 8b. Updated baseline map of the southeast section of the Sierra del Divisor Reserved Zone. Data: MINAM, SERNANP, USGS, IBC, Hansen/UMD/Google/USGS/NASA.

 

Image 8b is an updated map of the deforestation within the southeast section of the Sierra del Divisor Reserved Zone. Note that the new 2015 deforestation is found much deeper within the reserve than previous detected forest loss.

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

Confirming Recent Deforestation

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Image 8c. Landsat time-series (2014-2015) of the recent deforestation. Data: USGS.

To better understand how the recent deforestation unfolded, we created a satellite (Landsat) image time-series. Note that in Image 8c all four panels show the exact same area over time. In August 2014, our focal area was completely forested. The first evidence of deforestation is seen in May 2015. In June 2015, the deforestation grows quickly.

 

 

 

 

 

 

 

 

 

 

 

Deforestation Within the Isconahua Territorial Reserve

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Image 8d. Deforestation within the Territorial Reserve Isconahua. Data: MINAM, SERNANP, USGS, IBC, Hansen/UMD/Google/USGS/NASA.

 

Image 8d shows the new deforestation is also located with the Isconahua Territorial Reserve.

This is an official land designation in favor of indigenous peoples in isolation, to protect their rights, habitat, and the conditions that ensure their existence and integrity as a people.

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

SERNANP Response

In response to this article, SERNANP (the Peruvian protected areas agency) issued this statement:

“The Sierra del Divisor Reserved Zone is a transitional area under the Peruvian National Service of Natural Protected Areas (SERNANP).

Over the past few years, Sierra del Divisor has made significant efforts in its fight against ilegal logging and other activities that threaten it. However, it is worth noting that Image of the Week #8: New Deforestation Detected Within Sierra del Divisor (Peru) in June corresponds with an area of overlap with the Isconahua Territorial Reserve, a sector in which the Ministry of Culture works in coordination with SERNANP.

As part of our actions, SERNANP has planned a flyover in the zone to verify information regarding the new deforestation alert in the Sierra del Divisor, and will continue with special park guard patrolling that began last week, despite the local climate conditions.”

+++

“La Zona Reservada Sierra del Divisor es un espacio de carácter transitorio a cargo del Servicio Nacional de Áreas Naturales Protegidas por el Estado (SERNANP).

En los últimos años la ZRSD ha realizado grandes esfuerzos en su lucha contra la tala ilegal y otras actividades que la amenazan. Sin embargo, hay que precisar que la Imagen de la Semana #8: Nueva Deforestación al Interior de la ZRSD corresponde al ámbito de traslape (superposición) con la Reserva Territorial Isconahua, donde también interviene el Ministerio de Cultura, la cual el SERNANP trabaja de manera conjunta con dicho sector.

En el marco de nuestras acciones, el SERNANP viene programando un sobrevuelo en la zona para verificar la información sobre la nueva alerta de deforestación en la ZRSD, y continuar con el patrullaje especial del personal guardaparque que viene realizando desde la semana pasada, pese a las condiciones climáticas del lugar”.

Cita

Finer M, Novoa S, Peña N (2015) Nueva Deforestación al Interior de la Zona Reservada Sierra del Divisor. MAAP: Imagen #8. Link: https://www.maapprogram.org/2015/06/imagen-8-sierradivisor

Image #7: Sierra del Divisor – Growing Threats Highlight Importance of Creating National Park

As the Peruvian Government decides whether the Sierra del Divisor Reserved Zone should become a National Park, here in Image of the Week #7 we offer this new analysis of the current deforestation patterns of the area. A Reserved Zone classification, which was applied to Sierra del Divisor in 2006, is a temporary measure to protect an area of biological importance until the government is able to determine a final designation. National Park status represents the strongest possible final designation and would lead to strengthened legal protections to confront the growing array of threats we document below (namely, illegal coca, logging, mining activities).

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Image of the Week 7a. Deforestation patterns within and around the proposed Sierra del Divisor National Park. Key data sources: MINAM, SERNANP, USGS, IBC, MINAGRI, Hansen/UMD/Google/USGS/NASA.

Key Findings:

We have detected several deforestation fronts within and around the current Sierra del Divisor Reserved Zone. These findings demonstrate the need for the stronger legal protections that would come with National Park status.

Most notably, we detected within and around the current  Reserved Zone (and proposed National Park):

– Deforestation for illegal coca cultivation within the southwestern section (Zoom #1).

– New logging roads near both the southern and northwestern sections (Zooms #1 and #2).

– Deforestation associated with illegal logging camps within the southeastern section (Zoom #3). This illegal logging is within the Isconahua Territorial Reserve, an official land classification designed to protect the territory of indigenous peoples in isolation.

– Gold mining near the southern section (Zoom #3).

Background: From Reserved Zone to National Park

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Image 7b. The current (left panel) and potential (right panel) scenario for the Sierra del Divisor region

Image 7b illustrates the current (left panel) and potential (right panel) scenario for the Sierra del Divisor region.

The vast majority of the Reserved Zone would become a National Park under the current proposal pending before the Peruvian government. The proposed Sierra del Divisor National Park covers a vast area (1,354,485 hectares) in the far eastern Peruvian Amazon (departments of Loreto and Ucayali), adjacent to the Brazilian border.

Note that several sections on the western side of the Reserved Zone would not be included, however. Part of the excluded area, in the northwest, will remain as a Reserved Zone and may be part of a future proposal for a Regional Conservation Area known.

 

 

 

 

 

Coca and Logging Roads in Southwestern Section (Zoom #1)

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Image 7c. Zoom #1: Enhanced view of the southwestern section of the proposed national park. Panels A and B are high resolution satellite images of the areas indicated on the main map on the left. Key data sources: MINAM, SERNANP, ACCA, Hansen/UMD/Google/USGS/NASA, USGS, SPOT 6.

Image 7c provides an enhanced view of the southwestern section of the proposed National Park. It highlights an expanding deforestation cluster — 130 hectares between 2013 and 2014 — on the upper Calleria River (see “A” on the map). Our analysis indicates that illegal coca cultivation is the cause of this deforestation. Panel A shows a high resolution satellite image of this deforestation.

Also note that a new road is being constructed near the southwestern park boundary (see “B” on the map). We presume it to be a logging road because it passes through a forestry concession. Most notably, there was significant new construction in both 2013 and 2014, indicating that the road is in active use. In addition, high resolution imagery (see panel B) shows road width of about 30 meters, indicating that it may be designed for larger vehicles and heavy machinery.

Logging Road Approaching Northwestern Section (Zoom #2)

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Image 7d. Zoom #2: Enhanced view of the northwestern section of the proposed national park. Key data sources: USGS, SERNANP, GOREL.

Image 7d provides an enhanced view of the northwestern section of the proposed National Park, showing the construction of another new logging road. We presume that it is a logging road because it is passing through forestry concessions with no other obvious destination. Most notably, there was new construction in 2013, 2014, and 2015 indicating that is an active logging road.

Also note the expanding deforestation, especially in 2014, outside of the town of Contamana, indicating the importance of creating a Regional Conservation Area in this area adjacent to the proposed National Park.

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

Illegal Logging and Gold Mining in Southeastern Section (Zoom #3)

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Image 7e. Zoom #3: Enhanced view of the southeastern section of the proposed national park. Panels A, B, and C are high resolution satellite images of the areas indicated on the main map on the left. Key data sources: MINAM, SERNANP, ACCA, Hansen/UMD/Google/USGS/NASA, USGS, and SPOT 6.

Image 7e provides an enhanced view of the southeastern section of the Proposed National park. It highlights that both illegal logging (see “A” on the map) and gold mining (see “B” and “C” on the map) are present.

It is important to emphasize that this southeast section is part of the Isconahua Territorial Reserve administered by the Ministry of Culture. This is an official land designation in favor of indigenous peoples in isolation, to protect their rights, habitat, and the conditions that ensure their existence and integrity as a people.

Regarding the illegal logging, our analysis indicates the deforestation within the proposed National Park along the upper Shesha River is caused by a series of logging camps. Panel A shows a high resolution satellite image of this deforestation. This illegal logging is within the Isconahua Territorial Reserve.

Regarding the gold mining, there are two principal zones causing deforestation, one along the Shesha River and the other along the Abujao River. Panels B and C show high resolution images of these two mining areas. The headwaters of both river systems are born in the proposed park.

SERNANP Response

In response to this article, SERNANP (the Peruvian protected areas agency) issued this statement:

La Zona Reservada Sierra del Divisor es un espacio de carácter transitorio a cargo del Servicio Nacional de Áreas Naturales Protegidas por el Estado (SERNANP).  La zona aledaña a esta área acoge a 14 Comunidades Nativas, las cuales aprovechan los servicios ecosistémicos en beneficio de más de 500 familias.

En los últimos años la ZRSD ha logrado mejores resultados en su lucha contra la tala ilegal enfrentando esta amenaza sobre todo en espacios de ámbito de las reservas territoriales, y continúa alerta por la deforestación asociada al cultivo ilícito de coca que se reporta en esta parte del país.

En ese marco, se ha reportado desde el 2011 a los sectores correspondientes para su incorporación dentro del Plan Anual de Reducción del Espacio Cocalero de tal forma que se haga frente a esta amenaza de manera estratégica.

Data Description:

Background map is a mosaic of four Landsat 8 images (30 m resolution) from August and September 2014. Any variation of green indicates forest cover. Note there is some scattered cloud cover. Data is from USGS.

Protected areas are darker green. Data for the proposed Sierra del Divisor National Park comes from its technical document (expediente técnico).

Black indicates areas that were deforested as of 2000 according to data from the Peruvian Environment Ministry (MINAM 2009). Yellow (2000-2006), red (2007-2012), and purple (2013) indicate areas that were deforested from 2000 to 2013 according to data published by Hansen et al. 2013 (Science 342: 850–53; Data download).

Pink and teal indicate areas that were deforested between 2014 and early 2015 based on our analysis of Landsat imagery using CLASlite forest monitoring software.

Citation

Finer M, Novoa S (2015) Sierra del Divisor: Growing Threats Highlight Importance of Creating National Park. MAAP Image #7. Link: https://www.maapprogram.org/2015/06/image-7-sierra-del-divisor/